When a charged particle is placed between two charged plates, it will experience a force due to the electric field created by the plates. The particle will move in the direction of the force, either towards the positively charged plate or the negatively charged plate, depending on the charge of the particle and the plates.
The charged particle will experience a repulsive force due to the like charges, causing it to move away from the other particle. The magnitude of the force is directly proportional to the product of the charges and inversely proportional to the square of the distance between them.
When charged objects are placed near neutral objects, there can be a transfer of electrons between the objects, resulting in the neutral object becoming charged. The charged object can induce a separation of charges in the neutral object, causing it to attract or repel other nearby objects.
Examples of electric fields include the field between the plates of a charged capacitor, the field around a charged particle like an electron, and the field produced by a lightning bolt during a storm. These fields represent the force that a test charge would experience if placed within them.
The space around a particle through which an electric charge can exert force is referred to as the electric field. This field exists at all points in space and its strength diminishes with distance from the charged particle according to an inverse square law. Other charged particles placed in this electric field will experience a force due to the interactions between their charges.
The two particles will repel each other due to the like charges. This repulsion force will push the particles away from each other. The strength of the repulsion force depends on the charges of the particles and their distance from each other.
they either attract or repel
The charged particle will experience a repulsive force due to the like charges, causing it to move away from the other particle. The magnitude of the force is directly proportional to the product of the charges and inversely proportional to the square of the distance between them.
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When charged objects are placed near neutral objects, there can be a transfer of electrons between the objects, resulting in the neutral object becoming charged. The charged object can induce a separation of charges in the neutral object, causing it to attract or repel other nearby objects.
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Depending on the charge colloidal particles are attracted to catode or anode.
Examples of electric fields include the field between the plates of a charged capacitor, the field around a charged particle like an electron, and the field produced by a lightning bolt during a storm. These fields represent the force that a test charge would experience if placed within them.
They scoot away from each other
The force between two charged particles in a medium will depend on the properties of the medium, such as its dielectric constant. The force will be reduced compared to if the particles were in a vacuum, due to the screening effect of the medium on the electric field between the charges. The force will be weaker as the dielectric constant of the medium increases.
The space around a particle through which an electric charge can exert force is referred to as the electric field. This field exists at all points in space and its strength diminishes with distance from the charged particle according to an inverse square law. Other charged particles placed in this electric field will experience a force due to the interactions between their charges.
The two particles will repel each other due to the like charges. This repulsion force will push the particles away from each other. The strength of the repulsion force depends on the charges of the particles and their distance from each other.
When a charged particle is placed in an electric field, it experiences a force due to the field. This force causes the particle to accelerate in the direction of the field if the charge is positive, or in the opposite direction if the charge is negative. The motion of the particle will depend on its initial velocity and the strength and direction of the electric field.